Abstract
Bleaching patterns along a faulted succession provides new insight into fluid migration pathways controlled by the fault zone and mechanical stratigraphy. In order to investigate this effect, we logged stratigraphic layers in Humbug Flats, Utah, USA both in host rocks and faulted rocks, where a 40 m offset normal fault cuts through the Entrada Sandstone. We measured petrophysical and mechanical properties using TinyPerm II, Schmidt Hammer and laboratory core testing for selected layers. Bleaching has been identified as a proxy for fluid migration parallel to bedding, which fades out with distance from faults. A new observation is that fracturing of bed interfaces contributes to horizontal flow out from the fault zone. Longer-distance comprehensive bleaching dominates the most permeable beds (units), hosting porosity-controlled deformation band associated to fault zones. Fractures prevail in low permeability and stiffer units, where isolated fracture parallel bleaching haloes are observed within fault damage and process zones. Strong correlation is observed between permeability/porosity and stiffness/strength properties for the tested samples of different layers along the stratigraphic logs. For the studied fault, fractures provide important conduits for vertical flow across low permeability and stiff layers, whereas the more porous layers provide bedding-parallel flow paths out of the fault zone.
Highlights
For centuries fluid flow in faulted sedimentary basins has been difficult to forecast (Faulkner et al, 2010)
Along-fault fluid flow cause layer-parallel sweep into parts of the local stratigraphy dictated by bed properties and in places fractures along bedding interfaces
For the mechanical stratigraphy within the Entrada Sandstone, strong correlations exist between permeability and stiffness, as well as between porosity and strength
Summary
For centuries fluid flow in faulted sedimentary basins has been difficult to forecast (Faulkner et al, 2010). The po tential for faults to act as vertical conduits is highly relevant for injection operations like CO2 storage, wastewater injection and reservoir pressure support. This challenge calls for more detailed mapping of the me chanical stratigraphy influencing the structural style of the fault (Ferrill et al, 2017) and the vertical fluid migration pathways like fracture corridors (Lunn et al, 2008; Ogata et al, 2014). Mobility of the reducing fluids in Utah has been attributed to several events
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